Chemical Constituents of Aristolochia rigida and Mutagenic Activity of

Johanna Michl , Geoffrey C. Kite , Stefan Wanke , Oliver Zierau , Guenter Vollmer , Christoph Neinhuis , Monique S. J. Simmonds , and Michael Heinrich...
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Jo-I of Natwd Pradwcts Vol. 56, NO.9,pp. 1605-1608, S@*

1605 1993

CHEMICAL CONSTITUENTS OF ARZSTOLOCHZA RZGZDA AND MUTAGENIC ACTIVITY OF ARISTOLOCHIC ACID IV L w P m , * E m NIERI, ANNA RITA B u ,ANTONIOMARSILI, Diprtimmto di Chimica Biaorgank, Universitd di Pisa, via Bonanno 33, 56126 Pisa, Italy and ROBERTO SCARPATO Diprtimmto di Srienzz del Tewitmio e dell’Ambiente,Uniwsitd di Pisa, via S. Giuseppe 22, 56126 Pisa, Italy ARSTRACT.-TWO aristolochic acids 12 and 31 and a hvonol glycoside 1 have been isolated from Aristolwhia r i g i h (Aristolochiaceae).Aristolochic acid IV 121, the most abundant constituent, has shown a weak direct mutagenic activity in the Ames test: this action seems to be inhibited, at least in part,by metabolic reactions.

Aristolochia rigida Duch. (Aristolochiaceae)is a herbaceous plant widespread near Mogadisho (Somalia); it is carefully avoided by herbaceous animals and apparently not attacked by insects. Although this plant is not used in folk medicine in the region where it grows, we were prompted to investigate it, both because no chemical and biological studies on this plant have been reported in the literature and because plants belonging to the same genus appear to contain substances endowed with interesting biological properties (1). The aerial parts ofA. rigidz (1.18kg) were defatted with n-hexane and then extracted with Me,CO at room temperature. The Me,CO extract yielded a glycoside, which showed a positive Shinoda test (2) and uv absorptions at 264, 298 (sh), and 349 nm, typical of the flavonoid nucleus (3). The molecular formula C,,H3,,01, was deduced both from el-

emental analysis and from fabms in positive ion mode, whose most representative peaks, besides the quasi-molecular peak at m/z 595 EM+H]+, were at m/z 449 I(M+H)- 146If, which suggested the loss of a deoxyhexoseunit, and at m/z 287 f449- 162]+, resulting from cleavage of a hexose unit, thus showing that the aglycone unit had the formula CI5Hl6O6. This permitted us the deduction that the compound was a flavonoid deoxyglycosylglycoside. Indeed, acid hydrolysis affordedkaempferol,galactose,and rhamnose. More precise information about the structure of the flavonoid glycoside was obtained from its ‘H- and 13C-nmrspectra (see Experimental). Comparison of the spectral data with those reported in the literature permitted identification of the compound as kaempferol-3-0-P-Drobinobioside fl](4). From the Same extract, aristolochic acids IV 121 and IVa 131 were also ob-

bl 1 R=H

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constituent of A. rigiah. Therefore, we decided to submit aristolochic acid IV 121 to the Ames test (7). Mutagenicity tests, using the plate incorporation assay for Salmonella ryphimurium strain TA100, were carried out. In order to simulate the metabolic activation process that takes place in vivo, the rat liver enzyme system S9 (7) was added to the plates. The mutagenic assays were carried out in triplicate, and the number of his' revertent colonies was scored, after incubation for 48 h. Aristolochic acid IV increased the number of his' revertants up to 100 pg/ plate without toxic effects. At 500 pg/ plate a toxic effect took place, shown by the growth of single resistant colonies. The toxicity was more evident at 1000 pg/plate, 2500 pg/plate, and 5000 pg/ plate: under these conditions, the absence of a cell layer was observed, and the toxic effects took place when the substance was assayed either with or without S9. The statistically significant dose-response curve (r=0.924;p